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Sensory Training - MiOTA

Sensory Training :translating research to clinical practice & home programNel Ledesma, MHS, OTR/LRehabilitation ServicesBeaumont Health System Troy CampusOctober 10, 2019 Course Objectives Discuss the prevalence of Sensory impairment following a stroke Describe the stroke survivors experiences of Sensory impairment in the upper limb and impact with daily life Review Sensory assessments and outcome measures Review the adaptive / compensatory strategies for Sensory impairment Discuss the passive and active Sensory Training Discuss the recommended parameters, electrodes placements and dosage for passive Sensory Training using TENS Discuss Thermal Stimulation to improve thermal awareness Identify sample objects for active Sensory Training Describe Sensory Training home program Present case studies2 Stroke Statistics Stroke kills about140,000

–Increased sensitivity to touch & pain ... Lack of knowledge & training on evidence-based interventions to effectively address sensory loss / dysfunction • Despite high incidence of sensory impairments post-stroke, studies of somatosensory retraining programs are limited

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Transcription of Sensory Training - MiOTA

1 Sensory Training :translating research to clinical practice & home programNel Ledesma, MHS, OTR/LRehabilitation ServicesBeaumont Health System Troy CampusOctober 10, 2019 Course Objectives Discuss the prevalence of Sensory impairment following a stroke Describe the stroke survivors experiences of Sensory impairment in the upper limb and impact with daily life Review Sensory assessments and outcome measures Review the adaptive / compensatory strategies for Sensory impairment Discuss the passive and active Sensory Training Discuss the recommended parameters, electrodes placements and dosage for passive Sensory Training using TENS Discuss Thermal Stimulation to improve thermal awareness Identify sample objects for active Sensory Training Describe Sensory Training home program Present case studies2 Stroke Statistics Stroke kills about140,000 Americans each year that s1 out of every 20 Someone in the United States has a stroke every40 seconds.

2 Every4 minutes, someone dies of Every year, more than795,000 peoplein the United States have a stroke. About 610,000 of these are first or new About 185,00 strokes nearly 1 of 4 are in people who have had a previous About87%of all strokes areischemic strokes, in which blood flow to the brain is Economic impact was estimated at$34 billioneach total includes the cost of health care services, medicines to treat stroke, and missed days of stroke dysfunction Stroke is a leading cause of serious long-term Sensation is commonly impaired after stroke Sensory impairments are associated with stroke severity, decreased motor function.

3 And are prognostic factor for treatment outcomes 6,7,8 Sensory deficits can prolong the duration of hospital stay and negatively affect a person s ability to use the upper limb4 Incidence of Sensory dysfunction Individuals with right hemisphere brain lesions have been reported to have a higher incidence of post stroke Sensory dysfunction (37%) compared with those with left hemisphere lesions (25%)8 Damage to the parietal lobe (where the somatosensory cortex is located) and damage to the thalamus and brainstem (which relay Sensory information to the cortex) can cause sensation issues.

4 Sensory problems post stroke differ from one person to another. 5 Sensory Cortex6 Sensory Homunculus7 Parietal Lobe located near the center of the brain (upper middle lobe of each cerebral hemisphere), behind the frontal lobe, in front of the occipital lobe, and above the temporal lobe interprets Sensory information, such as letting us know the location of parts of our body and aiding in physical navigation integrates Sensory information among various modalities, including spatial sense and navigation (proprioception), the main Sensory receptive area for the sense of touch (mechanoreception)

5 In the somatosensory cortex helps determine your own orientation in space, as well as the orientation of other objects. It also receives significant input from the hand, suggesting that it helps coordinate fine motor skills and Sensory input from the hands. functions in processing Sensory information from the various parts of the body. It is heavily related to the sense of touch and involved in the manipulation of objects, as well as in detecting the orientation and numbers of objects encountered. It is also an essential element of spatial information, which gives us the ability to judge size, distance, and functions as an important relay and integrative station forsensorysignals and motor information passing to all areas of thecerebral cortex, the basal ganglia, the hypothalamus, and the brainstem.

6 It also regulates consciousness, sleep and system14 Handles Sensory input from superficial sources such as the skin and deep sources such as musculoskeletal system Sensation is stimulated by receptors in the periphery of the body and the Sensory information travels to the brain by way of the spinal cord Somatosensory receptors: Mechanoreceptors respond to touch, pressure, stretch, & vibration Chemoreceptors respond to cell injury or damage Thermoreceptors respond to heat or cold Each of these receptors has a subset called nociceptors which sense pain when stimulated1510 Sensory Pathways Spinothalamic pathway Anterior spinothalamic crude touch & pressure Lateral spinothalamic pain & temperature Posterior/Dorsal column pathway fine touch, pressure, vibration.

7 Proprioception Spinocerebellar pathway proprioceptive information11 Major Ascending Pathways for the Somatic Senses Spinocerebellar: proprioception from skeletal muscles to cerebellum of same side (don t cross); large fibers Posterior (Dorsal) column: discriminative touch sensation through thalamus to somatosensory cortex (cross in medulla); large fibers Spinothalamic (Anterolateral): carries non-discriminate sensations through the thalamus to the primary somatosensory cortex (cross on spinal cord before ascending); small fibers12 Posterior column pathway13 Motor pathways Lateral pathway voluntary control over skeletal muscles Lateral corticospinal tract controls distal muscles Anterior corticospinal tract controls proximal muscles Rubrospinal tract control of muscle tone in flexor muscle group Anterior Medial pathway muscle tone and gross movement of the trunk (posture & balance)

8 And proximal limb Vestibulospinal tract maintain head and eye coordination, upright posture and balance, and conscious realization of spatial orientation and motion Reticulopsinal tract Tectospinal tract coordinates head & eye movements Anterior corticospinal tract controls proximal muscles14 Frequency of Sensory / somatosensory impairment after stroke Connell, LA (2008)9 7 53% had impaired tactile sensations 31 89% impaired stereognosis 34 64% impaired proprioception Proprioception & stereognosis were more frequently impaired than tactile sensations Carey, L & Matyas, T (2011)10 47% had touch discrimination impairment on affected hand contralateral to the lesion & 16% experienced impairment on ipsilesional unaffected hand 49% showed impaired limb position sense (proprioception)

9 In the affected limb & 20% on unaffected limb Concern has been expressed by authors about the validity of using the uninvolved limb as the normal reference in testing because of evidence of bilateral Sensory impairment 815 Stroke Survivors self-reported experiences of upper limb Sensory impairmentsCarlsson H, (2018) qualitative study, 15 participants Changed & varied perception of sensation Affected movement control Problems using the upper limb (UL) in daily life Various strategies to cope with the upper limb disability Lack of Sensory training16 Stroke Survivors self-reported experiences of upper limb Sensory impairmentsCarlsson H, (2018) qualitative study, 15 participants Changed & varied perception of sensation Numbness (fingertips were asleep similar to dental anesthesia)

10 , tingling, burning sensation some c/o UL was not alive, others reported feeling of heaviness Changes in temperature sensitivity sensitive to cold even if they wore gloves, delay in perception of heat Increased sensitivity to touch & pain Affected movement control Difficulty adjusting the grip force used too much pressure when holding or manipulating objects because they were afraid of dropping; some reported they had lost their automatic movements & had to increase their concentration when holding or carrying task object resulting in increased mental fatigue Proprioceptive & perceptual difficulties difficulty performing smooth movements w/precision, difficulty recognizing small objects with their hand w/o vision or identifying an object in their pocket by touch alone 17 Stroke Survivors self-reported experiences of upper limb Sensory impairmentsCarlsson H, (2018)


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